Caspartin and Calprismin, Two Protiens of the Shell Calcitic Prsims of the Mediterranean Fan Mussle Pinna nobilis

Frédéric Marin et al JBC 2005

Two proteins were isolated one is 38-kDA (calprismin) another one is  17kDA(caspartin). Caspartin forms mutlimers and self-aggregates and inhibits the precipitation of calcium carbonate precipitation in vitro. Caspartin is found between the prsims and the surrounding insoluble sheets, this suggests the prominent role of aspartic acid-rich proteins for the building of calcitic prsims among mollusks.


Role of water-soluble matrix fraction, extracted from the nacre of Pincatada maxima, in the regulation of cell activity in abalone mantle cell culture (Halioitis tuberculata)

D.Sud, D. Doumenc, E. Lopez, C. Milet

In the Abalone Haloits tuberculata, they have established a cell culture of the mantle tissue, they used MTT to assess the viablility of cells,  they used the water soluble extract of the organic matrix, on the cell culture, the WSM reduced the viability of cells, but yet increased the activity of alkaline phosphatase. Hemocytes and eptithelial cells are known to cooperate with mantle cells in shell regeneration and in pearl production (awaji & Suziki 1995). It appears that the WSM of P.maxima controls, mantle cell activity.

Evolution of Nacre: Biochemistry and Proteomics of the Shell Organic Matrix of the Cephalopod Nautilus macromphalus

In mollusks, one of the most widely studied shell textures is nacre, the lustrous aragonitic layer that constitutes the internal components of the shells of several bivalves, a few gastropods, and one cephalopod: the nautilus. Nacre contains a minor or- ganic fraction, which displays a wide range of functions in relation to the biomineralization process. Here, we have biochemi- cally characterized the nacre matrix of the cephalopod Nautilus macromphalus. The acid-soluble matrix contains a mixture of polydisperse and discrete proteins and glycoproteins, which interact with the formation of calcite crystals. In addition, a few bind calcium ions. Furthermore, we have used a proteomic approach, which was applied to the acetic acid-soluble and insoluble shell matrices, as well as to spots obtained after 2D gel electrophoresis. Our data demonstrate that the insoluble and soluble matrices, although different in their bulk monosacchar- ide and amino acid compositions, contain numerous shared peptides. Strikingly, most of the obtained partial sequences are entirely new. A few only partly match with bivalvian nacre pro- teins. Our findings have implications for knowledge of the long-term evolution of molluskan nacre matrices.

An interesting feature, of these molluscan protiens , is the Tyrosinase domains which seems to be unique to molluscs, one possibility is its realtionship to hemocyanins

Tyrosinase () PUBMED:3130643 is a copper monooxygenases that catalyzes the hydroxylation of monophenols and the oxidation of o-diphenols to o-quinols. This enzyme, found in prokaryotes as well as in eukaryotes, is involved in the formation of pigments such as melanins and other polyphenolic compounds. Tyrosinase binds two copper ions (CuA and CuB). Each of the two copper ions has been shown PUBMED:1901488 to be bound by three conserved histidines residues. The regions around these copper-binding ligands are well conserved and also shared by some hemocyanins, which are copper-containing oxygen carriers from the hemolymph of many molluscs and arthropods PUBMED:2664531, PUBMED:1898774. At least two proteins related to tyrosinase are known to exist in mammals, and include TRP-1 (TYRP1) PUBMED:7813420, which is responsible for the conversion of 5,6-dihydro-xyindole-2-carboxylic acid (DHICA) to indole-5,6-quinone-2-carboxylic acid; and TRP-2 (TYRP2) PUBMED:1537334, which is the melanogenic enzyme  DOPAchrome tautomerase () that catalyzes the conversion of DOPAchrome to DHICA. TRP-2 differs from tyrosinases and TRP-1 in that it binds two zinc ions instead of copper PUBMED:7980602. Other proteins that belong to this family are plant polyphenol oxidases (PPO) (), which catalyze the oxidation
of mono- and o-diphenols to o-diquinones PUBMED:1391768; and  Caenorhabditis elegans hypothetical protein C02C2.1.

check out these proteins full of Tyrosinase 😉


Dentin Matrix Protein 1 Regulates Dentin Sialophosphoprotein Gene Transcription during Early Odontoblast Differentiation

Dentin matrix protein 1 regulates dentin sialophosphoprotein gene transcription during early odontoblast differentiation.

Dentin mineralization requires transcriptional mechanisms to induce a cascade of gene expression for progressive develop- ment of the odontoblast phenotype. During cytodifferentiation of odontoblasts there is a constant change of actively tran- scribed genes. Thus, tissue-specific matrix genes that are silenced in early differentiation are expressed during the termi- nal differentiation process. Dentin sialophosphoprotein (DSPP) is an extracellular matrix, prototypical dentin, and a bone-spe- cific gene, however, the molecular mechanisms by which it is temporally and spatially regulated are not clear. In this report, we demonstrate that dentin matrix protein 1 (DMP1), which is localized in the nucleus during early differentiation of odonto- blasts, is able to bind specifically with the DSPP promoter and activate its transcription. We have identified the specific pro- moter sequence that binds specifically to the carboxyl end of DMP1. The DNA binding domain in DMP1 resides between amino acids 420 and 489. A chromatin immunoprecipitation assay confirmed the in vivo association of DMP1 with the DSPP promoter. Interactions between DMP1 and DSPP promoter thus provide the foundation to understand how DMP1 regulates the expression of the DSPP gene.

Dentin Sialophosphoprotein (DSPP) in Biomineralization

Two of the proteins found in significant quantity in the extracellular matrix (ECM) of dentin are dentin phosphoprotein (DPP) and dentin sialoprotein (DSP). DPP, the most abundant of the non-collagenous proteins in dentin is an unusually polyanionic protein, containing a large number of aspartic acids (Asp) and phosphoserines (Pse) in the repeating sequences of (Asp-Pse)n. and (Asp-Pse-Pse)n. The many negatively charged regions of DPP are thought to promote mineralization by binding calcium and presenting it to collagen fibers at the mineralization front during the formation of dentin. This purported role of DPP is supported by a sizeable pool of in vitro mineralization data showing that DPP is an important initiator and modulator for the formation and growth of hydroxyapatite crystals. Quite differently, DSP is a glycoprotein, with little or no phosphate. DPP and DSP are the cleavage products of dentin sialophosphoprotein (DSPP). Human and mouse genetic studies have demonstrated that mutations in, or knockout of, the Dspp gene result in mineralization defects in dentin and/or bone. The discoveries in the past 40 years with regard to DPP, DSP and DSPP have greatly enhanced our understanding of biomineralization and set a new stage for future studies. In this review, we summarize the important and new developments made in the past four decades regarding the structure and regulation of the DSPP gene, the biochemical characteristics of DSPP, DPP and DSP, as well as the cell/tissue localizations and functions of these molecules.

Of course, we know what is coming next right? 😉